DE102011114506A1 - Method and device for non-contact measurement of a mass or volume flow of an electrically conductive fluid - Google Patents

Abstract

The invention relates to a method and a device for non-contact measurement of a mass or volume flow of an electrically conductive fluid by means of Lorentz force compensation. The object is achieved with a method for non-contact measurement of the mass or volume flow (v1) of an electrically conductive fluid, wherein at the location of the flow, a magnetic field is generated and due to the relative movement between the magnetic field and the mass or volume flow (v1 ) is detected, wherein the mass or volume flow (v1) is superimposed in the magnetic field with a second known flow of another electrically conductive fluid (v2) or a moving electrically conductive solid body (4, 5) of known speed and off the speed known to flow of the fluid to be measured is determined and solved with a device for non-contact speed measurement of the mass or volume flow (v1) in a tubular vessel (1) flowing electrically conductive fluid in which generates a magnetic field at the location of the flow will and one on Because of the relative movement between the magnetic field and the mass or volume flow (v1) resulting force or moment component is detected, wherein parallel to the tubular or channel-shaped channel (1) another tubular or channel-shaped channel (2), in which flows another fluid , Is arranged so that the field lines of a magnet (3) both channels (1, 2) penetrate and an evaluation unit for detecting the resulting force or torque components is present.

Description

The invention relates to a method and a device for non-contact measurement of a mass or volume flow of an electrically conductive fluid by means of Lorentz force compensation.

The measurement of the flow velocity by conventional measuring methods such as impellers, pitot tubes and the like, is not possible in metal, semiconductor and glass melts, because erosion leads to the destruction of the measuring sensors. Therefore, non-contact electromagnetic flow measuring methods are used for high-temperature melting.

A non-contact electromagnetic measurement technique called Lorentz force anemometry is used in DE 10 2005 046 910 B4 described. The method is used for non-contact inspection of moving in pipes or gutters electrically conductive substances. It is based on the generation of a magnetic field at the location of the flow through a magnet system and on the measurement of the Lorentz force acting on the magnet system by the flow. With the aid of a magnet system which can be used flexibly, a primary magnetic field is coupled into the substance to be inspected, and with a suitable measuring system, the force and moment components arising from the relative movement between the primary magnetic field and the substance to be inspected and acting on the magnet system are detected.

Analogous methods are in JP 57199917 A , and WO 00/58695 A1 specified.

A disadvantage of these methods is that the measurement signal depends not only on the speed, but also on the magnetic field strength. If the magnetic field strength changes due to temperature variations or aging of the magnetic material, measurement errors will occur. Furthermore, the flow measurement must often take place in the presence of already existing external magnetic fields "interference fields". This is the case, for example, in flow measurement in liquid aluminum in an aluminum reduction cell. The measurement by means of Lorentz force anemometry is made more difficult by the fact that a DC magnetic field of the order of magnitude of 0.1 Tesla prevails in the aluminum reduction cell, which exerts a strong, speed-independent attractive force on the magnet system of a Lorentz force anemometer and would falsify a measurement.

The object of the invention is therefore to provide a method and a device with which these measurement errors are avoided.

The object is achieved with a method having the features specified in claim 1 and with a device having the features specified in claim 9 or 12, solved.

Advantageous embodiments of the invention are the subject of the dependent claims.

The unknown flow (mass flow or volume flow) v ₁ in the magnetic field to be measured is superposed with a second known flow v _{2 of} an easily handled electrically conductive fluid or a moving electrically conductive solid of known speed. As a result of this superimposition, the resulting Lorentz force is a superposition of the Lorentz force generated by the unknown flow and the force due to the second known flow or the known velocity of the solid. The resulting Lorentz force can be adjusted by a control to a specific, constant value or a time course can be specifically excited.

From the then known or much easier to measure flow v _{2 of} the desired flow v ₁ can be calculated very easily.

An advantageous embodiment provides that the known flow is used to compensate for the Lorentz force that this disappears. For this, the flow must be regulated so that the force signal of the Lorentz force measurement is zero.

Furthermore, it is possible to use the known movement of an electrically conductive solid in such a way to compensate for the Lorentz force that it disappears. The movement will be regulated so that the force signal of the Lorentz force measurement becomes zero.

The person skilled in suitable embodiments of such a scheme are familiar.

An advantageous form of movement is the rotational movement, because it runs endlessly. The direction of movement of the solid is opposite to the direction of movement of the fluid; the amount depends on the design and the conductivities.

The flow measurement of the potentially aggressive medium is thus attributed to the measurement of a velocity or an angular velocity outside the fluid.

From the then known or much easier to be measured speed of the desired flow can be determined.

The known flow or the known movement can also be used to determine the characteristic curve of the Lorentz force anemometer by determining the size of the output signal of the Lorentz force measurement when the input signal is known. This can be done at any number of points on the characteristic curve. For a linear characteristic at least two points are necessary.

Embodiments of the invention will be explained in more detail below with reference to a drawing.

Show:

1 an arrangement with an additional fluid,

2 an arrangement with two additional fluids,

3 an arrangement with a rotating disk,

4 an arrangement with two rotating discs and

5 an arrangement with a rotating hollow cylinder.

Corresponding parts are provided in all figures with the same reference numerals.

In 1 an arrangement is shown in which the fluid to be examined in a tubular or channel-shaped channel 1 flows at the speed v ₁ to be determined. Parallel to the canal 1 is another tubular or channel-shaped channel 2 arranged, which is flowed through by another fluid whose flow velocity v ₂ . Both channels are from the magnetic field of a magnet 3 penetrated. The unknown flow velocity v ₁ to be determined is superimposed with a second flow velocity v _{2 of} an easily handled electrically conductive fluid. The person skilled in easily manageable electrically conductive fluids, such as electrolytes or low-melting metals and alloys are known. From the known or much easier to measure flow velocity v ₂ , the sought flow velocity v ₁ can be calculated very easily. This purpose is served by an evaluation unit, not shown here, with which the resulting magnetic flux or a Lorentz force caused thereby is determined, which represents a measure of the flow velocity v ₁ to be determined.

The cross sections of channel 1 and the additional channel 2 can be the same or different. The spatial arrangement can be carried out equally horizontally or vertically.

2 shows an embodiment in which two further tubular or channel-shaped channels 2.1 and 2.2 are attached. Thus, two reference currents of the magnetic effect of the fluid to be determined and thus the Lorentz forces caused to be superimposed. This embodiment is advantageously used for the investigation of arrangements with non-linear field properties.

An embodiment in which, instead of a reference current, a moving electrically conductive component in the form of a disk 4 is used in 3 shown. The disc 4 rotates on a rotational axis arranged at right angles to the flow direction of the fluid.

4 shows an embodiment in which a rotating disc ( 4.1 ) and an additional rotating disc ( 4.2 ) are arranged on a common axis.

At the in 5 illustrated embodiment rotates a hollow cylinder 5 around a right angle to the flow axis arranged axis of rotation, so that the lateral surface of the hollow cylinder 5 from the magnetic field of the magnet 3 is detected.

LIST OF REFERENCE NUMBERS

1

tubular or channel-shaped channel for the fluid to be examined

2

tubular or channel-shaped channel for another fluid

2.1, 2.2

more channels

3

magnet

4

turntable

4.1

rotating disc

4.2

additional rotating disc

5

hollow cylinder

v ₁

Flow velocity of the fluid to be examined

v ₂

Flow rate of another fluid

S

magnetic south pole

N

magnetic north pole

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102005046910 B4 [0003]
• JP 57199917A [0004]
• WO 00/58695 A1 [0004]

Claims (17)

Method for non-contact measurement of the mass or volume flow of an electrically conductive fluid in which a magnetic field is generated at the location of the flow and a force or moment component resulting from the relative movement between the magnetic field and the mass or volume flow is detected, characterized in that Mass or volume flow in the magnetic field with a second known flow of another electrically conductive fluid or a moving electrically conductive solid body of known speed is superimposed and is determined from the known speed of flow of the fluid to be measured. A method according to claim 1, characterized in that the direction of flow of the further fluid or the solid is opposite to the direction of the fluid to be measured. A method according to claim 1 or 2, characterized in that the known flow is controlled so that the force or moment component assumes a particular value or temporal waveform. A method according to claim 1, 2 or 3, characterized in that the known flow is controlled so that the force or moment component is zero. A method according to claim 1 or 2, characterized in that a known movement of the electrically conductive solid is used to superimpose the Lorentz force such that the movement is controlled so that the force or moment component assumes a particular value or temporal signal waveform. A method according to claim 1, 2 or 5, characterized in that a known movement of the electrically conductive solid is used to compensate for the Lorentz force, that this disappears by the movement is controlled so that the force or torque signal of Lorentz force measurement is zero. The method of claim 1, 2, 5 or 6, characterized in that a certain distribution of the conductivity or material thickness of the moving electrically conductive solid body with uniform movement generates a time-varying waveform. A method according to claim 1, 2, 5, 6 or 7, characterized in that the known movement is a rotary movement. Apparatus for non-contact speed measurement of the mass or volume flow of a in a tubular or channel-shaped channel ( 1 ) flowing electrically conductive fluid in which a magnetic field is generated at the location of the flow and a force or moment component resulting from the relative movement between the magnetic field and the mass or volume flow is detected, characterized in that adjacent to the tubular or channel-shaped channel ( 1 ) another tubular or channel-shaped channel ( 2 ), in which another fluid flows, is arranged so that the field lines of a magnet ( 3 ) both channels ( 1 . 2 ) and an evaluation unit for detecting the flow in the other channel is present. Device according to claim 9, characterized in that as magnet ( 3 ) a permanent magnet is used. Apparatus according to claim 9 or 10, characterized in that parallel to the tubular or channel-shaped channel ( 1 ) two further tubular or channel-shaped channel ( 2.1 . 2.2 ) are arranged. Device for the non-contact speed measurement of the mass or volume flow of a vessel in a tubular vessel ( 1 ) flowing electrically conductive fluid in which at the location of the flow, a magnetic field is generated and due to the relative movement between the magnetic field and the mass or volume flow resulting force or moment component is detected, characterized in that a moving electrically conductive component of the magnetic field of the magnet ( 3 ) is detected and an evaluation unit for detecting the speed of the moving component is present. Apparatus according to claim 12, characterized in that the moving electrically conductive component has a certain distribution of conductivity or material thickness. Apparatus according to claim 12 or 13, characterized in that as a moving electrically conductive component a disc ( 4 ) is used, which rotates on a rotational axis arranged at right angles to the flow direction of the fluid. Apparatus according to claim 14, characterized in that an additional rotating disc ( 4.2 ) is arranged. Apparatus according to claim 15, characterized in that the rotating disc ( 4.1 ) and the additional rotating disc ( 4.2 ) are operated at the same angular velocity. Apparatus according to claim 12 or 13, characterized in that the moving electrically conductive component in the form of a hollow cylinder ( 5 ) and rotates on a right angle to the flow direction of the fluid arranged axis of rotation.

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